Spore germination is an essential developmental stage in the life cycle of many filamentous fungi. Arbuscular mycorrhizal fungi (AMF) form a number of different infectious propagules that increase their potential to colonize roots. Among them are extraradical and intraradical spores. The spore cell wall plays a major role in the survival of these propagules by being a physical and osmotic barrier. Because a cell can make considerable adjustments to the composition and structure of its wall in response to environmental conditions, it is possible that intraradical and extraradical spore walls show different mechanical and osmotic properties affecting their survival and germination. However, in contrast to the knowledge on the genetics and molecular composition of AMF cell wall, little is known about its mechanical properties. Information on the germination of AMF under hypertonic conditions is scarce, and experimental designs and methodologies have generally not allowed the direct effects of high external osmotic pressure on fungal germination to be separated from plant-mediated effects. This study had the goal to address two important sets of questions regarding the behavior of mycorrhizal spores. We first determined the relationship between cell wall composition, structure and mechanical properties of the model fungus Glomus irregulare. Micro-indentation was used to quantitatively measure the cell wall mechanical properties. Cell wall composition (chitin and glomalin content) was studied by immunofluorescence whereas optical microscopy was used to measure the cell wall thickness. Glomalin local density and wall thickness were both significantly higher for extraradical spore walls while chitin local density and rigidity were unaffected by origin of spores. High variability in results prevented us from identifying a primary factor responsible for overall wall strength during compression. Decreases of chitin and glomalin concentrations were correlated to the development of the fungal wall throughout its life-cycle. There was also differential association within the wall layers: The chitin and glomalin polymers were localized mostly in the outer and inner walls, respectively. In the second part of our work, we explored the direct effects of fertilizers, in relation to their water activity (aw), on spore germination and cellular turgor pressure. Spores were exposed to three fertilizers with different aw and spore germination and cytorrhysis of spores were assessed after different times of incubation. Water activities of the fertilizers were used as indicators of their osmotic pressures. Osmotic shock exposure of the Glomus irregulare spores to fertilizers at aw values between 0.982 and 0.882 caused gradual changes in cytorrhysis and germination. With the increase of external turgor pressure, cytorrhysis increased while the rate of germination decreased. These effects were most pronounced at high nutrient concentrations. The present investigation, while likely representing a significant step forward in understanding the mechanical and osmotic properties of AMF spores, also confirms that they might depend on many, as yet unidentified factors. Future research should examine differences in the physiology to discern reasons for such differences in spore properties.